CN113478672A - Pre-crushing equipment of banburying of tire manufacturing - Google Patents

Abstract

The invention relates to pre-crushing equipment, in particular to banburying pre-crushing equipment for tire manufacturing, which comprises a cooling crushing mechanism, a carbon black powder removing mechanism and a desulfurization mechanism, wherein the equipment can crush, can discharge harmful gas while cooling the crushing process by using double air flows, can serve as a large air purifier, can remove carbon black powder and desulfurize, and is connected with the carbon black powder removing mechanism.

Description

Pre-crushing equipment of banburying of tire manufacturing

Technical Field

The invention relates to a pre-crushing device, in particular to a pre-crushing device for banburying in tire manufacturing.

Background

In the production process of tires, banburying is a very important link, the traditional banburying has a crushing link, but the integrated crushing function is easily affected by high temperature, and waste gas generated in banburying is treated separately, so that the subsequent treatment pressure is increased due to the hysteresis effect of treatment, and the banburying pre-crushing equipment for manufacturing tires is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing banburying pre-crushing equipment for tire manufacturing, the equipment can crush, the equipment can utilize double air flows to cool the crushing process and simultaneously discharge harmful gases, the whole equipment can be used as a large air purifier, the equipment can remove carbon black powder, and the equipment can perform desulfurization.

In order to solve the technical problem, the invention relates to pre-crushing equipment, in particular to banburying pre-crushing equipment for tire manufacturing, which comprises a cooling crushing mechanism, a carbon black powder removing mechanism and a desulfurization mechanism, wherein the equipment can crush, harmful gas is discharged while the equipment can cool the crushing process by utilizing double air flows, the whole equipment can serve as a large air purifier, carbon black powder can be removed by the equipment, and desulfurization can be carried out by the equipment.

The cooling and crushing mechanism is connected with the carbon black powder removing mechanism, and the carbon black powder removing mechanism is connected with the desulfurization mechanism;

the carbon black powder removing mechanism comprises a base, a belt pulley I, a motor I, a belt I, a connecting plate, a belt pulley II, a fixed pipe, a powder removing box, an air outlet pipe I, a double-layer belt seat filter plate, a chute, a screw rod, a secondary support, a belt shaft powder baffle plate, a slide rod, a spring, an ash removing wheel seat, an ash removing wheel, an embedded groove, a servo motor and a coupling, wherein the base is connected with the motor I, the motor I is connected with the belt pulley I, the belt pulley I is in friction connection with the belt pulley I, the belt I is in friction connection with the belt pulley II, the connecting plate is connected with the slide rod, the slide rod is in sliding connection with the powder removing box, the slide rod penetrates through the powder removing box and is connected to the ash removing wheel seat, the ash removing wheel seat is in rotating connection with the ash removing wheel, the spring is sleeved on the slide rod, two ends of the spring are respectively connected to the powder removing box and the ash removing wheel seat, the fixed pipe is connected and communicated with the powder removing box, the powder removing box is connected and communicated with the air outlet pipe I, the double-layer belt seat is in sliding connection with the filter plate embedded groove, the embedded groove is arranged on the upper inner wall and the lower inner wall of the powder removing box, the double-layer filter plate with the seat is connected in the sliding groove in a sliding manner, the sliding groove is arranged on the powder removing box, the lead screw is rotatably connected with the powder removing box, the lead screw is in threaded connection with the double-layer filter plate with the seat, the upper end of the secondary support is connected on the powder removing box, the lower end of the secondary support is connected on the base, the powder baffle with the shaft is rotatably connected with the powder removing box, the powder baffle with the shaft is connected with the belt pulley II, the servo motor is connected with the shaft coupling, the shaft coupling is connected with the lead screw, the servo motor is connected with the powder removing box, the grinding box with the supporting legs is connected with the base, the motor is connected with the base, the air outlet pipe is rotatably connected with the fixed pipe and keeps communicated with the fixed pipe, the cooling and grinding mechanism for contacting the ash removing wheel with the powder baffle with the shaft comprises a grinding box with the supporting legs, a hollow rotating shaft, a U-shaped pipe, a pipe support, a hollow rotating shaft I, a feeding hopper, a belt, a motor belt, a gear and a gear, An air outlet pipe, a gear with a shaft I, a bearing seat, a gear I, a negative pressure pipe I, a grinding wheel I, a negative pressure box, a filtering baffle plate, a discharge port, blades and blades I, wherein the grinding box with supporting legs is rotationally connected with a hollow rotating shaft, the hollow rotating shaft is rotationally connected with a U-shaped pipe, the U-shaped pipe is connected with a pipe support, the pipe support is connected with the grinding box with supporting legs, the U-shaped pipe is rotationally connected with the hollow rotating shaft I, the hollow rotating shaft I is rotationally connected with the grinding box with supporting legs, a feed hopper is arranged on the upper end surface of the grinding box with supporting legs, the belt pulley is in frictional connection with a belt, the belt is in frictional connection with a motor belt pulley, the motor belt pulley is connected with a motor, the gear is connected with the air outlet pipe, the air outlet pipe is connected with the hollow rotating shaft and communicated with the gear, the gear is meshed with the gear with the shaft I, the belt shaft gear I is rotatably connected with the bearing seat, the bearing seat is connected with the grinding box with the supporting legs, the belt shaft gear is rotatably connected with the bearing seat, the belt shaft gear I is meshed with the gear I, the gear I is connected with the negative pressure pipe, the negative pressure pipe is connected and communicated with the hollow rotating shaft I, the negative pressure pipe is rotatably connected with the negative pressure pipe I, the negative pressure pipe I is fixedly connected onto the grinding box with the supporting legs, one end of the negative pressure pipe I is connected and communicated with the negative pressure box, the negative pressure box is embedded into the inner wall of one side of the grinding box with the supporting legs, the grinding wheel is connected with the hollow rotating shaft I, the hollow rotating shaft is connected with the grinding wheel I, the grinding wheel and the grinding wheel I are arranged in a mutually staggered mode, the filtering baffle is clamped in the negative pressure box, the discharge port is arranged on the grinding box with the supporting legs, the blades are arranged in the hollow rotating shaft I, and the blades are arranged in the air outlet pipe.

As a further optimization of the technical scheme, the desulfurization mechanism of the banburying pre-crushing device for tire manufacturing comprises a belt seat support, a collecting hopper, an outflow through groove, a rotating box air port, a rotating box feeding port, a belt pulley III, a belt II, a driving motor, an exchange medium inlet pipe, an air outlet pipe II, an exchange box support, an L-shaped pipe, a door-shaped seat, a belt seat hollow pipe, a belt shaft pulley, a spring I, a turning seat, a connecting port, a communicating channel, a limiting boss and an arc part, wherein the belt seat support is provided with the collecting hopper and the outflow through groove, the collecting hopper is communicated with the outflow through groove, the rotating box air port and the rotating box feeding port are arranged on two sides of the rotating box, the rotating box is rotatably connected with the belt seat support, the belt pulley III is frictionally connected with the belt II, the belt II is frictionally connected with the rotating box, the belt pulley III is connected with the driving motor, and the exchange box are connected with the driving motor, an exchange box is provided with an exchange medium inlet pipe and an air outlet pipe II, the exchange box is connected with an exchange box support, the exchange box support is connected with a support with a seat, one end of an L-shaped pipe is connected and communicated with the exchange box, the L-shaped pipe is connected with the support with the seat, the other end of the L-shaped pipe is rotatably connected with a rotating box, the other end of the L-shaped pipe is communicated with a material inlet of the rotating box, a door-shaped seat is arranged on the rotating box, a hollow pipe with the seat is rotatably connected with a pulley with a shaft, the hollow pipe with the seat is slidably connected with the door-shaped seat, a spring I is sleeved on the hollow pipe with the seat, two ends of the spring I are respectively connected with the rotating box and a limiting boss, the limiting boss is connected with the hollow pipe with the seat, the limiting boss abuts against the door-shaped seat, a connecting port and a communicating channel are both arranged on the hollow pipe with the seat, the hollow pipe is communicated with the communicating channel, the hollow pipe with the rotating box is slidably connected with the rotating box, a turning seat is connected on the inner wall of the rotating box, and an air outlet pipe I is communicated with the air outlet pipe, the air outlet pipe I is rotatably connected with the rotating box, the base is connected with the support with the seat, and the support with the seat is provided with an arc part.

As a further optimization of the technical scheme, the rotation directions of the crushing wheel and the crushing wheel I of the banburying pre-crushing device for tire manufacturing are opposite, and when the crushing wheel and the crushing wheel I which are arranged in a staggered mode rotate, materials can be meshed between the crushing wheel and the crushing wheel I.

As a further optimization of the technical scheme, when the pulley with the shaft rotates along with the rotating box, the pulley with the shaft is extruded by the arc part, the pulley with the shaft drives the hollow tube with the seat to go deep into the rotating box, and when the spring I reaches the compression limit, the connecting port extends into the rotating box.

The banburying pre-crushing device for tire manufacturing has the beneficial effects that:

the banburying pre-crushing equipment for tire manufacturing can crush, can cool the crushing process by using double air flows and simultaneously discharge harmful gas, can serve as a large air purifier, can remove carbon black powder, and can perform desulfurization.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic diagram of a banburying pre-crushing device for tire manufacturing according to the present invention.

FIG. 2 is a schematic structural diagram II of an internal mixing pre-crushing device for tire manufacturing according to the present invention.

FIG. 3 is a schematic structural diagram III of an internal mixing pre-crushing device for tire manufacturing according to the present invention.

FIG. 4 is a schematic diagram of the structure of an internal mixing pre-crushing device for tire manufacturing according to the present invention.

Fig. 5 is a first schematic structural diagram of a cooling and pulverizing mechanism 1 of an internal mixing pre-pulverizing device for tire manufacturing according to the present invention.

Fig. 6 is a schematic structural diagram of a cooling crushing mechanism 1 of an internal mixing pre-crushing device for tire manufacturing according to the present invention.

Fig. 7 is a partially enlarged view of the second schematic structural diagram of the cooling and pulverizing mechanism 1 of the banburying pre-pulverizing apparatus for tire manufacturing according to the present invention.

Fig. 8 is a schematic structural diagram three of the cooling and pulverizing mechanism 1 of the banburying pre-pulverizing device for tire manufacturing of the present invention.

Fig. 9 is a fourth schematic structural diagram of the cooling and pulverizing mechanism 1 of the banburying pre-pulverizing device for tire manufacturing according to the present invention.

Fig. 10 is a schematic structural diagram five of the cooling and pulverizing mechanism 1 of the banburying pre-pulverizing device for tire manufacturing of the present invention.

Fig. 11 is a first schematic structural diagram of the carbon black powder removing mechanism 2 of the internal mixing pre-crushing device for tire manufacturing according to the present invention.

Fig. 12 is a second schematic structural diagram of the carbon black powder removing mechanism 2 of the banburying pre-crushing device for tire manufacturing according to the present invention.

Fig. 13 is a partially enlarged view of a second schematic structural diagram of the carbon black powder removing mechanism 2 of the banburying pre-crushing device for tire manufacturing according to the present invention.

Fig. 14 is a third schematic structural diagram of the carbon black powder removing mechanism 2 of the banburying pre-crushing device for tire manufacturing according to the present invention.

Fig. 15 is a first schematic structural diagram of a desulfurization mechanism 3 of an internal mixing pre-crushing device for tire manufacturing according to the present invention.

Fig. 16 is a partially enlarged view of a first schematic structural view of a desulfurization mechanism 3 of an internal mixing pre-crushing device for tire manufacturing according to the present invention.

Fig. 17 is a second schematic structural diagram of the desulfurization mechanism 3 of the banburying pre-crushing device for tire manufacturing according to the present invention.

Fig. 18 is a third schematic structural diagram of a desulfurization mechanism 3 of the banburying pre-crushing device for tire manufacturing according to the present invention.

Fig. 19 is a fourth schematic structural diagram of a desulfurization mechanism 3 of the banburying pre-crushing device for tire manufacturing according to the present invention.

Fig. 20 is a partial enlarged view of the fourth schematic structural view of the desulfurization mechanism 3 of the banburying pre-crushing apparatus for tire manufacturing in accordance with the present invention.

In the figure: a cooling and crushing mechanism 1; a crushing box 1-1 with supporting legs; a hollow rotating shaft 1-2; 1-3 of a U-shaped pipe; 1-4 of a pipe support; a hollow rotating shaft I1-5; 1-6 parts of a feed hopper; 1-7 of belt pulleys; 1-8 parts of a belt; 1-9 parts of a motor belt pulley; 1-10 of a motor; gears 1-11; 1-12 parts of an air outlet pipe; 1-13 of gears with shafts; a belt shaft gear I1-14; 1-15 of a bearing seat; gear I1-16; 1-17 parts of negative pressure pipe; negative pressure pipe I1-18; 1-19 of a crushing wheel; crushing wheels I1-20; 1-21 parts of a negative pressure box; 1-22 parts of a filtering baffle; a discharge port is 1-23; blades 1-24; blades I1-25; a carbon black powder removing mechanism 2; a base 2-1; pulley I2-2; motor I2-3; belt I2-4; 2-5 of a connecting plate; pulley II 2-6; 2-7 parts of a fixed pipe; 2-8 parts of a powder removing box; an air outlet pipe I2-9; 2-10 parts of a double-layer filter plate with a seat; 2-11 of a chute; 2-12 parts of a screw rod; 2-13 of secondary support; a powder baffle with a shaft 2-14; 2-15 parts of a slide bar; 2-16 parts of a spring; 2-17 parts of ash removal wheel seat; 2-18 parts of ash cleaning wheel; 2-19 of embedded groove; 2-20 parts of a servo motor; 2-21 of a coupler; a desulfurization mechanism 3; a belt seat support 3-1; a collection hopper 3-2; the flow-out through groove 3-3; rotating the box tuyere 3-4; 3-5 of a rotating box; rotating a box feeding port 3-6; pulley III 3-7; belt II 3-8; driving a motor 3-9; exchange medium inlet pipe 3-10; an air outlet pipe II 3-11; 3-12 parts of an exchange box; exchange box supports 3-13; 3-14 parts of L-shaped pipe; 3-15 of a door-shaped seat; hollow tube with base 3-16; pulley 3-17 with shaft; spring I3-18; 3-19 of a turnover seat; connecting ports 3-20; communication channels 3-21; 3-22 parts of a limiting boss; and arc parts 3-23.

Detailed Description

The first embodiment is as follows:

the present invention is described below with reference to fig. 1 to 20, and relates to a pre-pulverization apparatus, and more specifically, to a tire manufacturing banburying pre-pulverization apparatus, which includes a cooling pulverization mechanism 1, a soot removal mechanism 2, and a desulfurization mechanism 3, and is capable of pulverizing, and discharging harmful gas while cooling the pulverization process with a dual air flow, and the whole apparatus can serve as a large air cleaner, and can remove soot and perform desulfurization.

The cooling and crushing mechanism 1 is connected with the carbon black powder removing mechanism 2, and the carbon black powder removing mechanism 2 is connected with the desulfurization mechanism 3;

the cooling and crushing mechanism 1 comprises a crushing box 1-1 with supporting legs, a hollow rotating shaft 1-2, a U-shaped pipe 1-3, a pipe support 1-4, a hollow rotating shaft I1-5, a feed hopper 1-6, a belt pulley 1-7, a belt 1-8, a motor belt pulley 1-9, a motor 1-10, a gear 1-11, an air outlet pipe 1-12, a gear with a shaft 1-13, a gear with a shaft I1-14, a bearing seat 1-15, a gear I1-16, a negative pressure pipe 1-17, a negative pressure pipe I1-18, a crushing wheel 1-19, a crushing wheel I1-20, a negative pressure box 1-21, a filtering baffle 1-22, a discharge port 1-23, a blade 1-24 and a blade I1-25, wherein the crushing box 1-1 with supporting legs is rotatably connected with the hollow rotating shaft 1-2, the hollow rotating shaft 1-2 is rotatably connected with the U-shaped pipe 1-3, the U-shaped pipe 1-3 is connected with the pipe support 1-4, the pipe support 1-4 is connected with the grinding box with supporting legs 1-1, the U-shaped pipe 1-3 is rotatably connected with the hollow rotating shaft I1-5, the hollow rotating shaft I1-5 is rotatably connected with the grinding box with supporting legs 1-1, the upper end surface of the grinding box with supporting legs 1-1 is provided with a feed hopper 1-6, a belt pulley 1-7 is in frictional connection with a belt 1-8, the belt 1-8 is in frictional connection with a motor belt pulley 1-9, the motor belt pulley 1-9 is connected with a motor 1-10, a gear 1-11 is connected with an air outlet pipe 1-12, an air outlet pipe 1-12 is connected and communicated with the hollow rotating shaft 1-2, the gear 1-11 is meshed with a gear with a shaft 1-13, one end of a belt shaft gear 1-13 is connected with a belt pulley 1-7, the belt shaft gear 1-13 is meshed with a belt shaft gear I1-14, the belt shaft gear I1-14 is rotatably connected with a bearing seat 1-15, the bearing seat 1-15 is connected with a grinding box with supporting legs 1-1, the belt shaft gear 1-13 is rotatably connected with the bearing seat 1-15, the belt shaft gear I1-14 is meshed with a gear I1-16, the gear I1-16 is connected with a negative pressure pipe 1-17, the negative pressure pipe 1-17 is connected and communicated with a hollow rotating shaft I1-5, the negative pressure pipe 1-17 is rotatably connected with a negative pressure pipe I1-18, the negative pressure pipe I1-18 is fixedly connected with the grinding box with supporting legs 1-1, one end of the negative pressure pipe I1-18 is connected and communicated with the negative pressure box 1-21, the negative pressure box 1-21 is embedded into one side inner wall of the grinding box with supporting legs 1-1, the grinding wheels 1-19 are connected with a hollow rotating shaft I1-5, the hollow rotating shaft 1-2 is connected with a grinding wheel I1-20, the grinding wheels 1-19 and the grinding wheels I1-20 are arranged in a staggered way, the filtering baffle plates 1-22 are clamped in a negative pressure box 1-21, the discharge port 1-23 is arranged on the grinding box 1-1 with supporting legs, the blades 1-24 are arranged in the hollow rotating shaft I1-5, the blades I1-25 are arranged in an air outlet pipe 1-12, the motor belt pulleys 1-9 are driven to rotate by the operation of a motor 1-10, the motor belt pulleys 1-9 drive the belt pulleys 1-7 to rotate through a belt 1-8, the belt pulleys 1-7 drive the belt shaft gears 1-13 to rotate, the belt shaft gears 1-13 drive the air outlet pipe 1-12 to rotate through the meshing with the gears 1-11, the air outlet pipe 1-12 can drive the hollow rotating shaft 1-2 to rotate, the hollow rotating shaft 1-2 can drive the crushing wheel I1-20 to rotate, the belt shaft gear 1-13 can drive the belt gear I1-16 through the belt shaft gear I1-14 to rotate, the gear I1-16 can drive the negative pressure pipe 1-17 to rotate, the negative pressure pipe 1-17 can drive the hollow rotating shaft I1-5 to rotate, the hollow rotating shaft I1-5 can drive the crushing wheel 1-19 to rotate, when the crushing wheels 1-19 and the crushing wheel I1-20 which are arranged in a staggered mode rotate, materials can be meshed between the crushing wheels 1-19 and the crushing wheel I1-20, the materials are added from the feed hopper 1-6, and are discharged from the discharge port 1-23 after being meshed and crushed, so as to be subjected to internal mixing, when the hollow rotating shaft I1-5 rotates, the blades 1-24 rotating along with the rotation form airflow blown from the negative pressure pipe 1-17 to the hollow rotating shaft I1-5, when the hollow rotating shaft 1-2 rotates, the blades I1-25 rotating along with the rotation form airflow blown from the middle idle rotating shaft 1-2 to the blades I1-25, the airflow formed by the blades 1-24 enters the hollow rotating shaft 1-2 through the U-shaped pipe 1-3, so that the two airflows are superposed with each other, the airflow forms negative pressure at the filtering baffle plate 1-22, the dust and harmful gas generated in the crushing process are filtered once through the filtering baffle plate 1-22 and then enter the negative pressure pipe 1-17 through the negative pressure pipe I1-18, and then enter the hollow rotating shaft 1-2 through the hollow rotating shaft I1-5 and the U-shaped pipe 1-3, then the mixture enters the fixed pipes 2-7, and in the flowing process of the airflow, the heat generated in the crushing process can be taken away, so that the heat adhesion is prevented, and meanwhile, two openings of the feed hoppers 1-6 and the discharge ports 1-23 can be attracted by the airflow, so that the external dust and the like can be attracted away, and the function of a dust remover is achieved;

the carbon black powder removing mechanism 2 comprises a base 2-1, a belt pulley I2-2, a motor I2-3, a belt I2-4, a connecting plate 2-5, a belt pulley II2-6, a fixing pipe 2-7, a powder removing box 2-8, an air outlet pipe I2-9, a double-layer filter plate with a seat 2-10, a chute 2-11, a screw rod 2-12, a secondary support 2-13, a powder blocking plate with a shaft 2-14, a sliding rod 2-15, a spring 2-16, a dust cleaning wheel seat 2-17, a dust cleaning wheel 2-18, an embedded groove 2-19, a servo motor 2-20 and a coupling 2-21, wherein the base 2-1 is connected with the motor I2-3, the motor I2-3 is connected with the belt pulley I2-2, the belt pulley I2-2 is in friction connection with the belt I2-4, a belt I2-4 is in friction connection with a belt pulley II2-6, a connecting plate 2-5 is connected with a sliding rod 2-15, the sliding rod 2-15 is in sliding connection with a powder removing box 2-8, the sliding rod 2-15 penetrates through the powder removing box 2-8 and is connected with a deashing wheel seat 2-17, the deashing wheel seat 2-17 is in rotating connection with a deashing wheel 2-18, a spring 2-16 is sleeved on the sliding rod 2-15, two ends of the spring 2-16 are respectively connected with the powder removing box 2-8 and the deashing wheel seat 2-17, a fixed pipe 2-7 is connected and communicated with the powder removing box 2-8, the powder removing box 2-8 is connected and communicated with an air outlet pipe I2-9, a double-layer filter plate with a seat 2-10 is in sliding connection with an embedded groove 2-19, the embedded groove 2-19 is arranged on the upper inner wall and the lower inner wall of the powder removing box 2-8, the double-layer filter plate with the seat 2-10 is connected in the chute 2-11 in a sliding way, the chute 2-11 is arranged on the powder removing box 2-8, the screw rod 2-12 is rotationally connected with the powder removing box 2-8, the screw rod 2-12 is connected with the double-layer filter plate with the seat 2-10 in a threaded way, the upper end of the secondary support 2-13 is connected with the powder removing box 2-8, the lower end of the secondary support 2-13 is connected with the base 2-1, the powder baffle plate with the shaft 2-14 is rotationally connected with the powder removing box 2-8, the powder baffle plate with the shaft 2-14 is connected with the belt pulley II2-6, the servo motor 2-20 is connected with the shaft coupling 2-21, the shaft coupling 2-21 is connected with the screw rod 2-12, the servo motor 2-20 is connected with the powder removing box 2-8, the grinding box with the supporting legs 1-1 is connected with the base 2-1, the motor 1-10 is connected with the base 2-1, the air outlet pipe 1-12 is rotationally connected and communicated with the fixed pipe 2-7, the dust cleaning wheel 2-18 is contacted with the powder baffle plate with the shaft 2-14, when the airflow enters the powder removing box 2-8 from the fixed pipe 2-7, the running motor I2-3 can drive the belt pulley I2-2 to rotate, the belt pulley I2-2 can drive the belt pulley II2-6 to rotate through the belt I2-4, the belt pulley II2-6 can drive the powder baffle plate with the shaft 2-14 to rotate, the powder baffle plate with the shaft 2-14 can reduce the speed and adsorb the dust contained in the airflow, then the dust falls after the dust cleaning wheel 2-18 is contacted and cleaned, the rest dust is filtered by the double-layer filter plate with the seat 2-10 and then is discharged into the rotating box 3-5 through the air outlet pipe I2-9, when the double-layer filter plate with the seat 2-10 needs to be cleaned, the servo motor 2-20 is operated to drive the coupler 2-21 to rotate, the coupler 2-21 can drive the screw rod 2-12 to rotate, the screw rod 2-12 can drive the double-layer filter plate with the seat 2-10 to slide out of the embedded groove 2-19, at the moment, the double-layer filter plate with the seat 2-10 can be treated, and powder materials such as carbon black and the like cleaned by the ash cleaning wheel 2-18 can be collected and treated;

the desulfurization mechanism 3 comprises a belt seat support 3-1, a collecting hopper 3-2, an outflow through groove 3-3, a rotating box air port 3-4, a rotating box 3-5, a rotating box material inlet 3-6, a belt pulley III3-7, a belt II3-8, a driving motor 3-9, an exchange medium inlet pipe 3-10, an air outlet pipe II3-11, an exchange box 3-12, an exchange box support 3-13, an L-shaped pipe 3-14, a door-shaped seat 3-15, a belt seat hollow pipe 3-16, a belt shaft pulley 3-17, a spring I3-18, a turning seat 3-19, a connecting port 3-20, a communicating channel 3-21, a limiting boss 3-22 and an arc part 3-23, wherein the collecting hopper 3-2 and the outflow through groove 3-3 are arranged on the belt seat support 3-1, the material collecting hopper 3-2 is communicated with the outflow through groove 3-3, the rotating box air port 3-4 and the rotating box feeding port 3-6 are arranged at two sides of the rotating box 3-5, the rotating box 3-5 is rotationally connected with the belt seat support 3-1, the belt pulley III3-7 is frictionally connected with the belt II3-8, the belt II3-8 is frictionally connected with the rotating box 3-5, the belt pulley III3-7 is connected with the driving motor 3-9, the driving motor 3-9 is connected with the exchange box 3-12, the exchange box 3-12 is provided with an exchange medium inlet pipe 3-10 and an air outlet pipe II3-11, the exchange box 3-12 is connected with the exchange box support 3-13, the exchange box support 3-13 is connected with the belt seat support 3-1, one end of the L-shaped pipe 3-14 is connected and communicated with the exchange box 3-12, the L-shaped pipe 3-14 is connected with the support with a seat 3-1, the other end of the L-shaped pipe 3-14 is rotationally connected with the rotating box 3-5, the other end of the L-shaped pipe 3-14 is communicated with the feeding port of the rotating box 3-6, the door-shaped seat 3-15 is arranged on the rotating box 3-5, the hollow pipe 3-16 with a seat is rotationally connected with the pulley 3-17 with a shaft, the hollow pipe 3-16 with a seat is slidably connected with the door-shaped seat 3-15, the spring I3-18 is sleeved on the hollow pipe 3-16 with a seat, the two ends of the spring I3-18 are respectively connected with the rotating box 3-5 and the limit boss 3-22, the limit boss 3-22 is connected with the hollow pipe 3-16 with a seat, the limit boss 3-22 is abutted against the door-shaped seat 3-15, the connecting port 3-20 and the communicating channel 3-21 are both arranged on the hollow pipe seat 3-16 with a seat, the connecting port 3-20 is communicated with the communicating channel 3-21, the hollow tube with a seat 3-16 is connected with the rotating box 3-5 in a sliding way, the turning seat 3-19 is connected on the inner wall of the rotating box 3-5, the air inlet 3-4 of the rotating box is communicated with the air outlet tube I2-9, the air outlet tube I2-9 is connected with the rotating box 3-5 in a rotating way, the base 2-1 is connected with the support with a seat 3-1, the support with a seat 3-1 is provided with a circular arc part 3-23, when the air enters the rotating box 3-5, the exchange medium enters the tube 3-10 and is externally connected with a supplement tube of the exchange medium, the exchange medium enters the exchanging box 3-12 from the exchange medium inlet tube 3-10 and then flows into the rotating box 3-5 from the L-shaped tube 3-14, the running driving motor 3-9 can drive the belt pulley III3-7 to rotate, the belt pulley III3-7 can drive the rotating box 3-5 to rotate, the rotating box 3-5 can continuously turn up the exchange medium through the turning seat 3-19 to exchange contact with the air flow, the air flow is exchanged and then moves from the rotating box material inlet 3-6 to the L-shaped pipe 3-14 and is discharged from the air outlet pipe II3-11, the middle process always moves reversely with the exchange medium, thereby achieving the purpose of full desulfurization, when the belt shaft pulley 3-17 rotates along with the rotating box 3-5, the belt shaft pulley 3-17 can be extruded by the arc part 3-23, the belt shaft pulley 3-17 can drive the belt seat hollow pipe 3-16 to go deep into the rotating box 3-5, when the spring I3-18 reaches the compression limit, the connecting port 3-20 can extend into the rotating box 3-5, the exchanged waste liquid flows out from the connecting port 3-20 through the communicating channel 3-21 and then flows into the collecting hopper 3-2 from the outflow through groove 3-3, and a collecting container can be arranged below the collecting hopper 3-2 for collection.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1-20, and the embodiment is further described, wherein the rotation directions of the crushing wheels 1-19 and the crushing wheels I1-20 are opposite, and when the crushing wheels 1-19 and the crushing wheels I1-20 which are arranged in a staggered manner rotate, materials are engaged between the crushing wheels 1-19 and the crushing wheels I1-20.

The third concrete implementation mode:

the following describes the present embodiment with reference to fig. 1-20, and the present embodiment further describes the first embodiment, when the pulley 3-17 with shaft rotates along with the rotating box 3-5, the pulley 3-17 with shaft is pressed by the arc part 3-23, the pulley 3-17 with shaft drives the hollow tube 3-16 with seat to go deep into the rotating box 3-5, and when the spring I3-18 reaches the compression limit, the connecting port 3-20 extends into the rotating box 3-5.

The working principle of the device is as follows: the equipment can crush, the motor belt pulleys 1-9 are driven to rotate by the operation of the motors 1-10, the motor belt pulleys 1-9 can drive the belt pulleys 1-7 to rotate by the belts 1-8, the belt pulleys 1-7 can drive the belt shaft gears 1-13 to rotate, the belt shaft gears 1-13 can drive the air outlet pipes 1-12 to rotate by being meshed with the gears 1-11, the air outlet pipes 1-12 can drive the hollow rotating shafts 1-2 to rotate, the hollow rotating shafts 1-2 can drive the crushing wheels I1-20 to rotate, the belt shaft gears 1-13 can drive the belt shaft gears I1-16 of the belt shaft gears I1-14 to rotate, the gears I1-16 can drive the negative pressure pipes 1-17 to rotate, and the negative pressure pipes 1-17 can drive the hollow rotating shafts I1-5 to rotate, the hollow rotating shaft I1-5 can drive the crushing wheels 1-19 to rotate, when the crushing wheels 1-19 and the crushing wheels I1-20 which are arranged in a staggered mode rotate, materials can be meshed between the crushing wheels 1-19 and the crushing wheels I1-20, the materials are fed from the feed hoppers 1-6, and are discharged from the discharge ports 1-23 after being meshed and crushed, so that banburying can be conveniently carried out; the equipment can utilize double air flows to cool the crushing process and discharge harmful gas, the whole equipment can be used as a large air purifier, when the hollow rotating shaft I1-5 rotates, the blades 1-24 rotating along with the rotation can form air flow blown from the negative pressure pipe 1-17 to the hollow rotating shaft I1-5, when the hollow rotating shaft 1-2 rotates, the blades I1-25 rotating along with the rotation can form air flow blown from the middle idle rotating shaft 1-2 to the blades I1-25, the air flow formed by the blades 1-24 can enter the hollow rotating shaft 1-2 through the U-shaped pipe 1-3, so that the two air flows can play a mutual overlapping role, the air flow can form negative pressure at the filtering baffle plate 1-22, dust and harmful gas generated in the crushing process are filtered once through the filtering baffle plate 1-22 and then enter the negative pressure pipe 1-17 through the negative pressure pipe I1-18, then enters the hollow rotating shaft 1-2 through the hollow rotating shaft I1-5 and the U-shaped pipe 1-3 and then enters the fixed pipe 2-7, and in the flowing process of the airflow, the heat generated in the crushing process can be taken away to prevent the heat adhesion, and meanwhile, the openings at the two positions of the feed hopper 1-6 and the discharge port 1-23 can also be attracted by the airflow, so that the external dust and the like can be sucked away, and the effect of a dust remover is achieved; the device can remove carbon black powder, when airflow enters the powder removing box 2-8 from the fixed pipe 2-7, the running motor I2-3 can drive the belt pulley I2-2 to rotate, the belt pulley I2-2 can drive the belt pulley II2-6 to rotate through the belt I2-4, the belt pulley II2-6 can drive the belt shaft powder baffle 2-14 to rotate, the belt shaft powder baffle 2-14 can reduce the speed of dust contained in the airflow and adsorb the dust, then the dust is stalled and falls down after being cleaned by the contact of the dust cleaning wheel 2-18, the rest dust is filtered by the double-layer belt seat filter plate 2-10 and then is discharged into the rotating box 3-5 through the air outlet pipe I2-9, when the double-layer belt seat filter plate 2-10 needs to be cleaned, the servo motor 2-20 runs to drive the coupler 2-21 to rotate, the shaft coupling 2-21 drives the screw rod 2-12 to rotate, the screw rod 2-12 drives the double-layer filter plate with the seat 2-10 to slide out of the embedded groove 2-19, at the moment, the double-layer filter plate with the seat 2-10 can be processed, and meanwhile, powder materials such as carbon black and the like cleaned by the ash cleaning wheel 2-18 can be collected and processed; the equipment can carry out desulfurization, when gas enters the rotating box 3-5, the exchange medium inlet pipe 3-10 is externally connected with a supplement pipe of the exchange medium, the exchange medium enters the exchange box 3-12 from the exchange medium inlet pipe 3-10 and then flows into the rotating box 3-5 from the L-shaped pipe 3-14, the running driving motor 3-9 can drive the belt pulley III3-7 to rotate, the belt pulley III3-7 can drive the rotating box 3-5 to rotate, the rotating box 3-5 can continuously turn up the exchange medium through the turning seat 3-19 to carry out contact exchange with the gas flow, the exchange of the gas flow is carried out from the rotating box inlet 3-6 to the L-shaped pipe 3-14 and then discharged from the air outlet pipe II3-11, and the middle process always carries out reverse motion with the exchange medium, therefore, the purpose of full desulfurization is achieved, when the pulley 3-17 with the shaft rotates along with the rotating box 3-5, the pulley 3-17 with the shaft is extruded by the arc part 3-23, the pulley 3-17 with the shaft drives the hollow tube 3-16 with the seat to go deep into the rotating box 3-5, when the spring I3-18 reaches the compression limit, the connecting port 3-20 extends into the rotating box 3-5, the exchanged waste liquid flows out from the connecting port 3-20 through the communicating channel 3-21 and then flows into the collecting hopper 3-2 from the outflow through groove 3-3, and a collecting container can be arranged below the collecting hopper 3-2 for collection.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (5)

1. The utility model provides a pre-crushing equipment of banburying of tire manufacturing, includes cooling rubbing crusher structure (1), charcoal black powder removes mechanism (2), desulfurization mechanism (3), its characterized in that: the cooling and crushing mechanism (1) is connected with the carbon black powder removing mechanism (2), and the carbon black powder removing mechanism (2) is connected with the desulfurizing mechanism (3);

the cooling and crushing mechanism (1) comprises a crushing box (1-1) with supporting legs, a hollow rotating shaft (1-2), a U-shaped pipe (1-3), a pipe support (1-4), a hollow rotating shaft I (1-5), a feed hopper (1-6), belt pulleys (1-7), a belt (1-8), a motor belt pulley (1-9), a motor (1-10), gears (1-11), an air outlet pipe (1-12), shaft gears (1-13), shaft gears I (1-14), bearing seats (1-15), gears I (1-16), a negative pressure pipe (1-17), a negative pressure pipe I (1-18), crushing wheels (1-19), crushing wheels I (1-20), a negative pressure box (1-21), filtering baffles (1-22), A discharge port (1-23), blades (1-24) and blades I (1-25), a grinding box with supporting legs (1-1) is rotationally connected with a hollow rotating shaft (1-2), the hollow rotating shaft (1-2) is rotationally connected with a U-shaped pipe (1-3), the U-shaped pipe (1-3) is connected with a pipe support (1-4), the pipe support (1-4) is connected with the grinding box with supporting legs (1-1), the U-shaped pipe (1-3) is rotationally connected with a hollow rotating shaft I (1-5), the hollow rotating shaft I (1-5) is rotationally connected with the grinding box with supporting legs (1-1), a feed hopper (1-6) is arranged on the upper end face of the grinding box with supporting legs (1-1), a belt pulley (1-7) is in friction connection with a belt (1-8), the belt (1-8) is in friction connection with a motor belt pulley (1-9), the motor belt pulley (1-9) is connected with the motor (1-10), the gear (1-11) is connected with the air outlet pipe (1-12), the air outlet pipe (1-12) is connected and communicated with the hollow rotating shaft (1-2), the gear (1-11) is meshed with the gear with shaft (1-13), one end of the gear with shaft (1-13) is connected with the belt pulley (1-7), the gear with shaft (1-13) is meshed with the gear with shaft I (1-14), the gear with shaft I (1-14) is rotationally connected with the bearing seat (1-15), the bearing seat (1-15) is connected with the grinding box with supporting legs (1-1), the gear with shaft (1-13) is rotationally connected with the bearing seat (1-15), the gear with shaft I (1-14) is meshed with the gear I (1-16), the gears I (1-16) are connected with the negative pressure pipes (1-17), the negative pressure pipes (1-17) are connected and communicated with the hollow rotating shafts I (1-5), the negative pressure pipes (1-17) are rotationally connected with the negative pressure pipes I (1-18), the negative pressure pipes I (1-18) are fixedly connected with the grinding box (1-1) with the supporting legs, one end of each negative pressure pipe I (1-18) is connected and communicated with the negative pressure box (1-21), the negative pressure boxes (1-21) are embedded into the inner wall of one side of the grinding box (1-1) with the supporting legs, the grinding wheels (1-19) are connected with the hollow rotating shafts I (1-5), the hollow rotating shafts (1-2) are connected with the grinding wheels I (1-20), and the grinding wheels (1-19) and the grinding wheels I (1-20) are arranged in a staggered mode, the filtering baffle plates (1-22) are clamped in the negative pressure box (1-21), the discharge ports (1-23) are arranged on the grinding box (1-1) with the supporting legs, the blades (1-24) are arranged in the hollow rotating shaft I (1-5), and the blades I (1-25) are arranged in the air outlet pipe (1-12).

2. An internal mixing pre-crushing apparatus for tyre manufacture according to claim 1, characterised in that: the carbon black powder removing mechanism (2) comprises a base (2-1), a belt pulley I (2-2), a motor I (2-3), a belt I (2-4), a connecting plate (2-5), a belt pulley II (2-6), a fixed pipe (2-7), a powder removing box (2-8), an air outlet pipe I (2-9), a double-layer filter plate with a seat (2-10), a sliding chute (2-11), a screw rod (2-12), a secondary support (2-13), a powder blocking plate with a shaft (2-14), a sliding rod (2-15), a spring (2-16), a dust removing wheel seat (2-17), a dust removing wheel (2-18), an embedded groove (2-19), a servo motor (2-20) and a coupler (2-21), wherein the base (2-1) is connected with the motor I (2-3), the motor I (2-3) is connected with the belt pulley I (2-2), the belt pulley I (2-2) is in friction connection with the belt I (2-4), the belt I (2-4) is in friction connection with the belt pulley II (2-6), the connecting plate (2-5) is connected with the sliding rod (2-15), the sliding rod (2-15) is in sliding connection with the powder removing box (2-8), the sliding rod (2-15) penetrates through the powder removing box (2-8) and is connected with the ash removing wheel seat (2-17), the ash removing wheel seat (2-17) is in rotating connection with the ash removing wheel (2-18), the spring (2-16) is sleeved on the sliding rod (2-15), two ends of the spring (2-16) are respectively connected with the powder removing box (2-8) and the ash removing wheel seat (2-17), the fixed pipe (2-7) is connected and communicated with the powder removing box (2-8), the powder removing box (2-8) is connected and communicated with the air outlet pipe I (2-9), the double-layer filter plate with the seat (2-10) is connected with the embedded groove (2-19) in a sliding way, the embedded groove (2-19) is arranged on the upper inner wall and the lower inner wall of the powder removing box (2-8), the double-layer filter plate with the seat (2-10) is connected in the sliding groove (2-11) in a sliding way, the sliding groove (2-11) is arranged on the powder removing box (2-8), the screw rod (2-12) is rotationally connected with the powder removing box (2-8), the screw rod (2-12) is in threaded connection with the double-layer filter plate with the seat (2-10), the upper end of the secondary support (2-13) is connected on the powder removing box (2-8), the lower end of the secondary support (2-13) is connected on the base (2-1), the powder baffle plate with the shaft (2-14) is rotationally connected with the powder removing box (2-8), the belt shaft powder baffle (2-14) is connected with a belt pulley II (2-6), a servo motor (2-20) is connected with a shaft coupler (2-21), the shaft coupler (2-21) is connected with a screw rod (2-12), the servo motor (2-20) is connected with a powder removing box (2-8), a grinding box (1-1) with supporting legs is connected with a base (2-1), a motor (1-10) is connected with the base (2-1), an air outlet pipe (1-12) is rotatably connected with a fixed pipe (2-7) and keeps communicated, and an ash cleaning wheel (2-18) is in contact with the belt shaft powder baffle (2-14).

3. An internal mixing pre-crushing apparatus for tyre manufacture according to claim 2, characterized in that: the desulfurization mechanism (3) comprises a support with a seat (3-1), a collecting hopper (3-2), an outflow through groove (3-3), a rotating box air inlet (3-4), a rotating box (3-5), a rotating box material inlet (3-6), a belt pulley III (3-7), a belt II (3-8), a driving motor (3-9), an exchange medium inlet pipe (3-10), an air outlet pipe II (3-11), an exchange box (3-12), an exchange box support (3-13), an L-shaped pipe (3-14), a door-shaped seat (3-15), a hollow pipe with a seat (3-16), a pulley with a shaft (3-17), a spring I (3-18), a turnover seat (3-19), a connecting port (3-20), a communicating channel (3-21), A limiting boss (3-22), an arc part (3-23), a belt seat support (3-1) is provided with a material collecting hopper (3-2) and an outflow through groove (3-3), the material collecting hopper (3-2) is communicated with the outflow through groove (3-3), a rotating box air port (3-4) and a rotating box feeding port (3-6) are arranged at two sides of the rotating box (3-5), the rotating box (3-5) is rotationally connected with the belt seat support (3-1), a belt pulley III (3-7) is frictionally connected with a belt II (3-8), the belt II (3-8) is frictionally connected with the rotating box (3-5), the belt pulley III (3-7) is connected with a driving motor (3-9), the driving motor (3-9) is connected with an exchange box (3-12), an exchange medium inlet pipe (3-10) and an outlet pipe II (3-11) are arranged on an exchange box (3-12), the exchange box (3-12) is connected with an exchange box support (3-13), the exchange box support (3-13) is connected with a support with a seat (3-1), one end of an L-shaped pipe (3-14) is connected and communicated with the exchange box (3-12), an L-shaped pipe (3-14) is connected with the support with the seat (3-1), the other end of the L-shaped pipe (3-14) is rotationally connected with a rotating box (3-5), the other end of the L-shaped pipe (3-14) is communicated with a rotating box inlet (3-6), a door-shaped seat (3-15) is arranged on the rotating box (3-5), a hollow pipe (3-16) with a seat is rotationally connected with a pulley with a shaft (3-17), the hollow tube (3-16) with the seat is connected with the door-shaped seat (3-15) in a sliding way, the spring I (3-18) is sleeved on the hollow tube (3-16) with the seat, two ends of the spring I (3-18) are respectively connected with the rotating box (3-5) and the limiting boss (3-22), the limiting boss (3-22) is connected with the hollow tube (3-16) with the seat, the limiting boss (3-22) is propped against the door-shaped seat (3-15), the connecting port (3-20) and the communicating channel (3-21) are both arranged on the hollow tube (3-16) with the seat, the connecting port (3-20) is communicated with the communicating channel (3-21), the hollow tube (3-16) with the seat is connected with the rotating box (3-5) in a sliding way, the turning seat (3-19) is connected on the inner wall of the rotating box (3-5), the air port (3-4) of the rotary box is communicated with an air outlet pipe I (2-9), the air outlet pipe I (2-9) is rotatably connected with the rotary box (3-5), the base (2-1) is connected with the support (3-1) with the seat, and the support (3-1) with the seat is provided with an arc part (3-23).

4. An internal mixing pre-crushing apparatus for tyre manufacture according to claim 1, characterised in that: the rotation directions of the crushing wheels (1-19) and the crushing wheels I (1-20) are opposite, and when the crushing wheels (1-19) and the crushing wheels I (1-20) which are arranged in a staggered mode rotate, materials can be meshed between the crushing wheels (1-19) and the crushing wheels I (1-20).

5. An internal mixing pre-crushing apparatus for tyre manufacture according to claim 3, characterized in that: when the pulley (3-17) with the shaft rotates along with the rotating box (3-5), the pulley (3-17) with the shaft is extruded by the arc part (3-23), the pulley (3-17) with the shaft drives the hollow tube (3-16) with the seat to go deep into the rotating box (3-5), and when the spring I (3-18) reaches the compression limit, the connecting port (3-20) stretches into the rotating box (3-5).

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